Hybridised mechanistic and machine learning digital twins for modelling and optimising chemical processes in flow: a comparative analysis of parallel and series-based hybridisation
Hybridised mechanistic and machine learning digital twins for modelling and optimising chemical processes in flow: a comparative analysis of parallel and series-based hybridisation
In the field of chemical engineering, accurate prediction of reaction kinetics and concentration profiles is critical for the design and optimisation of industrial processes. However, achieving accurate predictions under variable or limited data conditions remains a major challenge. Despite the growing interest in hybrid models, a systematic comparison of parallel and series-based hybridisation strategies using empirical flow reactor data for digital twin applications has not yet been established. Here we show that PINN architecture can accurately predict concentration profiles and estimate reaction rate constants under both data-rich and data-scarce conditions, while the SPH+GA framework enhances spatial simulation fidelity and enables system-level optimisation through particle-based modelling. The same PINN architecture can be effectively applied in both forward and inverse modes, accurately predicting concentration profiles and estimating reaction rate constants with errors under 2%, even in data-scarce conditions. The SPH+GA framework enables detailed particle-level simulation and global optimisation, offering insight into spatial dynamics and reactor mixing. This series hybrid model achieved an R2 up to 0.91 and enabled flexible system tuning. These results underscore the broader value of hybrid mechanistic–machine learning frameworks, particularly for process environments with limited or noisy data. Our findings highlight that while PINNs offer high predictive accuracy and lower computational cost, SPH+GA excels in resolving spatial dynamics and supporting system characterisation. These parallel and series hybrid strategies demonstrate complementary strengths for building robust digital twins of chemical processes.
Digital twin, Genetic Algorithm, Hybrid modelling, Machine learning, Optimisation, Physics-Informed Neural Network, Plug flow reactor, Reaction kinetics, Smooth particle hydrodynamics
Nasruddin, Nur Aliya
54b6983d-8d15-4a85-b246-d70eca66851e
Islam, Nazrul
80176274-7453-4d4b-812c-ce7b22503c47
Vernuccio, Sergio
4bafd7f3-0943-4f6c-bc78-b4026516ccdb
Oyekan, John
6f644c7c-eeb0-4abc-ade0-53a126fe769a
10 June 2025
Nasruddin, Nur Aliya
54b6983d-8d15-4a85-b246-d70eca66851e
Islam, Nazrul
80176274-7453-4d4b-812c-ce7b22503c47
Vernuccio, Sergio
4bafd7f3-0943-4f6c-bc78-b4026516ccdb
Oyekan, John
6f644c7c-eeb0-4abc-ade0-53a126fe769a
Nasruddin, Nur Aliya, Islam, Nazrul, Vernuccio, Sergio and Oyekan, John
(2025)
Hybridised mechanistic and machine learning digital twins for modelling and optimising chemical processes in flow: a comparative analysis of parallel and series-based hybridisation.
Chemical Engineering Journal Advances, 23, [100775].
(doi:10.1016/j.ceja.2025.100775).
Abstract
In the field of chemical engineering, accurate prediction of reaction kinetics and concentration profiles is critical for the design and optimisation of industrial processes. However, achieving accurate predictions under variable or limited data conditions remains a major challenge. Despite the growing interest in hybrid models, a systematic comparison of parallel and series-based hybridisation strategies using empirical flow reactor data for digital twin applications has not yet been established. Here we show that PINN architecture can accurately predict concentration profiles and estimate reaction rate constants under both data-rich and data-scarce conditions, while the SPH+GA framework enhances spatial simulation fidelity and enables system-level optimisation through particle-based modelling. The same PINN architecture can be effectively applied in both forward and inverse modes, accurately predicting concentration profiles and estimating reaction rate constants with errors under 2%, even in data-scarce conditions. The SPH+GA framework enables detailed particle-level simulation and global optimisation, offering insight into spatial dynamics and reactor mixing. This series hybrid model achieved an R2 up to 0.91 and enabled flexible system tuning. These results underscore the broader value of hybrid mechanistic–machine learning frameworks, particularly for process environments with limited or noisy data. Our findings highlight that while PINNs offer high predictive accuracy and lower computational cost, SPH+GA excels in resolving spatial dynamics and supporting system characterisation. These parallel and series hybrid strategies demonstrate complementary strengths for building robust digital twins of chemical processes.
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Accepted/In Press date: 16 May 2025
e-pub ahead of print date: 2 June 2025
Published date: 10 June 2025
Keywords:
Digital twin, Genetic Algorithm, Hybrid modelling, Machine learning, Optimisation, Physics-Informed Neural Network, Plug flow reactor, Reaction kinetics, Smooth particle hydrodynamics
Identifiers
Local EPrints ID: 503546
URI: http://eprints.soton.ac.uk/id/eprint/503546
PURE UUID: d5758348-4937-4d59-a6c3-9b61c6fd7c15
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Date deposited: 05 Aug 2025 16:36
Last modified: 22 Aug 2025 02:46
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Contributors
Author:
Nur Aliya Nasruddin
Author:
Nazrul Islam
Author:
Sergio Vernuccio
Author:
John Oyekan
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